Team:ENSPS-Strasbourg/Background

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Revision as of 17:17, 27 October 2011 by Martin.A (Talk | contribs)

Introduction

Imagine that you could build a complete biosystem, with many biobricks involved in it, without complex laboratories experiences, fastidious studies, and in taking advantage of a complete Automation Design Software suite.


Global project:

The final aim of our project is to create a complete automated design tool to help the biologist during the whole Biosystem’s design flow :

Global scheme.png

The above scheme represents the final software suite we want to develop. Everything starts with an idea of a Biosystem, or a biological function, which leads to write some specifications and requirements. Then, as the microelectronics design flow uses HDL (High-level Description Languages), we could imagine that a description of this biosystem will be written with a “biologic description language” (best language to be defined). Then, a tool will translate it into a block diagram of elementary functions, in a high description level (only with input and output species, and different biological mechanisms). Another tool will find the best suitable BioBricks to realize the system, linked with a BioBrick registration database, which will give to the biologist the BioBricks involved into the system. Another part of this suite is to simulate the biosystem before building it. For that, and in using analogies between electronics and biology, the biosystem will be translated into an electronical equivalent, and this equivalent will be simulated into a conventional electronic simulator. Here, two simulations will be possible. Firstly, a behavioral simulation (binary model) will give to the biologist an idea of the behavior of the system, in putting different parameters (species present or not at the beginning for example). This simulation will validate the proof of concept. After that, another simulation will simulates in continuous-time the system (conservative model), and here the biologist will see the different interaction between species, the evolution of the concentrations into the system, and have an accurate idea of the transient states. This view of our work is an ideal view, and we are only at the beginning of the elaboration of this software tool. For us, this year, the aim of our work is to prove that a biological system can be simulated with an electronic equivalent by a conventional electronic simulator.


Our first step:

The initial part of our project is to prove that electronics and biology could be merged so as to build this kind of software tool. This year, we have decided to be focused on a crucial part of our project which is the simulation of biological mechanisms thanks to electronic tools. Then, by proving analogies between electronic and biological systems, we have built a software which simulates a system of biological devices as an electronic system. In other words, our work was aimed at translating biological mechanisms into a specific language understandable by conventional electronic simulators, so as to be able to virtually build a biosystem, and simulate it. In this way, we can take advantage of the powerfulness of electronic simulators for simulating complex systems in a reduced time. The global scheme of our year’s work is available below: